A method of forming one or more contact regions in a high-voltage field effect transistor (HFET) includes providing a semiconductor material, including a first active layer and a second active layer, with a gate dielectric disposed on a surface of the semiconductor material. A first contact to the semiconductor material is formed that extends through the second active layer into the first active layer, and a passivation layer is deposited, where the gate dielectric is disposed between the passivation layer and the second active layer. An interconnect is formed extending through the first passivation layer and coupled to the first contact. An interlayer dielectric is deposited proximate to the interconnect, and a plug is formed extending into the interlayer dielectric and coupled to the first portion of the interconnect.

A process of forming a field effect transistor is disclosed. The process includes steps of depositing a first silicon nitride (SiN) film on a semiconductor layer by a low pressure chemical vapor deposition (LPCVD) technique; depositing a second SiN film on the first SiN film by plasma assisted chemical vapor deposition (p-CVD) technique; preparing a photoresist mask on the second SiN film, the photoresist mask having an opening in a position corresponding to the gate electrode; dry-etching the second SiN film and the first SiN film continuously in a portion of the opening in the photoresist mask to form an opening in the first SiN film and an opening in the second SiN film, the openings in the first and second SiN films exposing the semiconductor layer; and filling at least the opening in the first SiN film by the gate electrode. A feature of the process is that the opening in the first SiN film has an inclined side against the semiconductor layer and gradually widens from the semiconductor layer.

A method of forming one or more contact regions in a high-voltage field effect transistor (HFET) includes providing a semiconductor material, including a first active layer and a second active layer, with a gate dielectric disposed on a surface of the semiconductor material. A first contact to the semiconductor material is formed that extends through the second active layer into the first active layer, and a passivation layer is deposited, where the gate dielectric is disposed between the passivation layer and the second active layer. An interconnect is formed extending through the first passivation layer and coupled to the first contact. An interlayer dielectric is deposited proximate to the interconnect, and a plug is formed extending into the interlayer dielectric and coupled to the first portion of the interconnect.

A process of forming a field effect transistor is disclosed. The process includes steps of depositing a first silicon nitride (SiN) film on a semiconductor layer by a low pressure chemical vapor deposition (LPCVD) technique; depositing a second SiN film on the first SiN film by plasma assisted chemical vapor deposition (p-CVD) technique; preparing a photoresist mask on the second SiN film, the photoresist mask having an opening in a position corresponding to the gate electrode; dry-etching the second SiN film and the first SiN film continuously in a portion of the opening in the photoresist mask to form an opening in the first SiN film and an opening in the second SiN film, the openings in the first and second SiN films exposing the semiconductor layer; and filling at least the opening in the first SiN film by the gate electrode. A feature of the process is that the opening in the first SiN film has an inclined side against the semiconductor layer and gradually widens from the semiconductor layer.

A method of forming one or more contact regions in a high-voltage field effect transistor (HFET) includes providing a semiconductor material, including a first active layer and a second active layer, with a gate dielectric disposed on a surface of the semiconductor material. A first contact to the semiconductor material is formed that extends through the second active layer into the first active layer, and a passivation layer is deposited, where the gate dielectric is disposed between the passivation layer and the second active layer. An interconnect is formed extending through the first passivation layer and coupled to the first contact. An interlayer dielectric is deposited proximate to the interconnect, and a plug is formed extending into the interlayer dielectric and coupled to the first portion of the interconnect.

Present application provides a method of manufacturing a semiconductor structure, including forming a well, forming a gate electrode over the well, implanting a lightly doped region in a first side of the well, implanting a first drain in the lightly doped region by a first depth, implanting a second drain in the lightly doped region by a second depth, implanting a source in a second side of the well, the second side being opposite to the first side. The second depth is greater than the first depth. The gate electrode is formed to cover a part of the lightly doped region and a part of the first drain.

A high electron mobility transistor includes a set of electrodes, such as a source, a drain, a top gate, and a side gate, and includes a semiconductor structure having a fin extending between the source and the drain. The top gate is arranged on top of the fin, and the side gate is arranged on a sidewall of the fin at a distance from the top gate. The semiconductor structure includes a cap layer positioned beneath the top gate and a channel layer arranged beneath the cap layer for providing electrical conduction. The cap layer includes nitride-based semiconductor material to enable a heterojunction forming a carrier channel between the source and the drain.

A perforating ohmic contact to a semiconductor layer in a semiconductor structure is provided. The perforating ohmic contact can include a set of perforating elements, which can include a set of metal protrusions laterally penetrating the semiconductor layer(s). The perforating elements can be separated from one another by a characteristic length scale selected based on a sheet resistance of the semiconductor layer and a contact resistance per unit length of a metal of the perforating ohmic contact contacting the semiconductor layer. The structure can be annealed using a set of conditions configured to ensure formation of the set of metal protrusions.

A high-voltage field effect transistor (HFET) includes a first active layer, a second active layer, and a layer of electrical charge disposed proximate to the first active layer and the second active layer. A gate dielectric is disposed proximate to the second active layer. A contact region in the HFET includes a contact coupled to supply or withdraw charge from the HFET, and a passivation layer disposed proximate to the contact and the gate dielectric. An interconnect extends through the passivation layer and is coupled to the contact. An interlayer dielectric is disposed proximate to the interconnect, and a plug extends into the interlayer dielectric and is coupled to the first portion of the interconnect.

A heterostructure device includes a channel layer, a barrier layer disposed on the channel layer, and a first electrode and a second electrode disposed on the barrier layer, respectively. The second electrode includes a p-type semiconductor structure and a raised section disposed on the p-type semiconductor structure, the second electrode includes a Schottky contact and an ohmic contact, the Schottky contact is formed between a top surface of the p-type semiconductor structure and a first bottom surface of the raised section, the ohmic contact is formed between a second bottom surface of the raised section and the barrier layer.